Drastic expression change of transposon-derived piRNA-like RNAs and microRNAs in early stages of chicken embryos implies a role in gastrulation

Recent studies have shown that endogenous small RNAs regulate a variety of biological processes during vertebrate development; however, little is known about the role of small RNAs in regulating developmental signaling pathways during early embryogenesis. In this study, we applied Illumina sequencing to characterize an unexpected endogenous small RNA catalog and demonstrated a dramatic transition from transposon-derived piRNA-like small RNAs (pilRNAs) to microRNAs (miRNAs) in pre- and post-gastrula chicken embryos. The comprehensive expression profile of chicken miRNAs at the pre- and post-gastrula stages revealed that most known and new miRNAs were dynamically regulated during development. In addition to embryonic stem cell-related miRNAs, Gene Ontology (GO) analysis showed that miRNAs enriched in early stage chicken embryos targeted multiple signal transduction pathways associated with the reproductive process and embryogenesis, including Wnt and TGF-β, which specifies the neural fate of blastodermal cells. Intriguingly, a large cohort of pilRNAs primarily derived from the active and most abundant transposable elements (TEs) were enriched in chicken stage X blastoderms. Within stage X blastoderms, pilRNAs were specifically localized to the primordial germ cells (PGCs), indicating their post-zygotic origin. Together, these findings imply a role for small RNAs in gastrulation in early stage chicken embryos.     

Cdk2ap1在不同性别鸡胚中的表达

为研究通过抑制消减杂交筛选出的cdk2ap1基因在鸡胚胎发育过程中的表达, 设计cdk2ap1引物并通过 RT-PCR扩增cdk2ap1基因片段, 构建cdk2ap1/pGEM-T重组质粒。以构建的重组质粒为模板, 使用Sp6和T7 RNA聚合酶合成地高辛(dig )标记的正、反义RNA探针, 借助胚胎整体原位杂交技术研究了cdk2ap1在雌雄鸡胚中的表达。结果表明cdk2ap1基因在4.0 d两性胚胎的脑间质、菱脑、听囊、脊神经管、前肢等部位均有表达, 且在雄性鸡胚中的表达量高于雌性; 在雄性鸡胚的生殖脊、后肢部位中该基因有表达但在雌性胚胎对应部位却基本没有表达。鉴于该基因在雌雄鸡胚中的差异表达, 推测cdk2ap1基因在鸡胚性别分化及性腺发育过程中起一定调节作用。     

The expression of gelatinase A (MMP-2) is required for normal development of zebrafish embryos

Gelatinase A, also called matrix metalloproteinase 2 (MMP-2), belongs to the matrix metalloproteinase (MMP) family. MMP-2 cleaves type IV collagen, denatured collagen (gelatin), and other extracellular matrix (ECM) components. MMP-2 has been reported to be involved in a number of biological and pathological processes, but previous studies have not indicated that its expression is essential for early embryogenesis. In the current study, we have utilized zebrafish as a developmental model to study the role of MMP-2 during embryogenesis. We have successfully isolated a zebrafish MMP-2 (zMMP-2) homologue showing over 80% identity and over 90% similarity to its human counterpart. In situ analysis showed that zMMP-2 was expressed as early as the one-cell stage implying a maternal origin during oogenesis, and embryos continued to express zMMP-2 through at least the 72-h stage of development. RT-PCR analysis confirmed the in situ expression pattern and gelatin zymography indicated that a metalloproteinase with the same gel mobility as vertebrate MMP-2 was present in zebrafish embryos. Injection of zMMP-2 antisense morpholino oligonucleotides into 1- to 4-cell embryos resulted in a truncated axis, monitored through 72 h of development indicating that this metalloproteinase plays an important role in zebrafish embryogenesis. Monpholino-induced alterations in development began to be observed at 12 h of embryogenesis based on morphological and axis marker studies. The results obtained in zebrafish are in contrast to murine knockout studies that indicate that MMP-2 does not have a major role in mouse embryogenesis.Edited by D. Tautz     

Temporal and spatial expression of TGF-beta2 in chicken somites during early embryonic development

A multifunctional growth and differentiation factor TGF-beta is expressed at various developmental stages, and its principle role may be involvement in organogenesis. The present study was performed to evaluate the temporal and spatial expression of TGF-beta2 mRNA in developing somites of chicken embryos during their early developmental periods. TGF-betas were expressed in various tissues of the whole embryo obtained at stage 26 (5 days of incubation) as revealed by whole-mount in situ hybridization. TGF-beta2 mRNA was predominantly expressed in somites as well as the head, branchial arch, wing buds, and leg buds. TGF-beta2 mRNA first appeared in the rostral somites on E4, and its expression sites expanded to the middle range of somites at stage 26. At stages 29-31 (6-7 days), expression in the rostral somites disappeared, and it appeared in the caudal somites. TGF-beta2 expression was also analyzed in sections of the embryo by in situ hybridization. The expression sites of TGF-beta2 were clearly observed in the myotomal somite tips as well as the neural tube. RT-PCR analysis showed that TGF-beta2 expression was very low in the blastocyte stage embryo and thereafter increased linearly in the whole trunk until stage 26. These data indicate that TGF-beta2 may be a regulatory factor participating in the somitogenesis of chicken embryos.     

Antisense inhibition of Xbrachyury impairs mesoderm formation in Xenopus embryos

Expression of the Xbrachyury (Xbra) gene was inhibited by antisense RNA synthesized in situ from an expression vector read by RNA polymerase III, injected into the fertilized egg or the 2-cell stage embryo of Xenopus laevis. Antisense-treated embryos had markedly reduced levels of Xbra mRNA and protein, and showed deficiencies in mesodermal derivatives and axis formation. In particular, organization of the posterior axis was affected, but often the anterior axis was also reduced. Some embryos failed to form mesoderm altogether and remained amorphous. The antisense effect is dose-dependent and may be "rescued" by overexpression of Xbra. In Xbra-deficient embryos, expression of several mesodermal genes (Xvent, pintallavis, Xlim, Xwnt-8 and noggin) was reduced to varying degrees, whereas goosecoid levels remained normal. The modified expression levels were partly normalized when Xbra deficiency was rescued. The observation that antisense inhibition yields slightly different phenotypes from dominant-negative inhibition suggests the recommendation of using several surrogate genetic approaches to determine the functional role of a gene in Xenopus development.     

Contribution of the superior atrioventricular cushion to the left ventricular infundibulum. Experimental study on the chick embryo

The role of the superior atrioventricular cushion in the normal development of the left ventricular infundibulum was experimentally studied in the chick embryo. 178 embryos at stages 19-24 of Hamburger and Hamilton were selectively labeled using gelatin-india ink; afterward embryos were reincubated until the mature heart stage, in which the final location of the labels was determined. In addition, anatomical microscopic studies were carried out on the chick embryo heart at different stages of the development. 91 embryos were obtained at the mature heart stage, 46 of which were normal. In 82,6% of these 46 embryos labels were found in the left ventricular infundibulum and were distributed in the following regions: (1) base of the free portion of the anteroseptal mitral leaflet (mitroaortic continuity); (2) the same region plus the left surface of the anterior basal portion of the ventricular septum, and (3) the left surface of the anterior basal portion of the ventricular septum. Anatomical microscopic studies showed that the superior atrioventricular cushion appears at stage 18, fusing with the inferior cushion at stage 28. Our results permit us to conclude that the superior atrioventricular cushion plays an important role in the normal development of the left ventricular infundibulum, and it contributes in the posterolateral and anteromedial wall formation.     

Zebrafish cypher is important for somite formation and heart development

Mammalian CYPHER (Oracle, KIA0613), a member of the PDZ-LIM family of proteins (Enigma/LMP-1, ENH, ZASP/Cypher, RIL, ALP, and CLP-36), has been associated with cardiac and muscular myopathies. Targeted deletion of Cypher in mice is neonatal lethal possibly caused by myopathies. To further investigate the role of cypher in development, we have cloned the zebrafish orthologue. We present here the gene, domain structure, and expression pattern of zebrafish cypher during development. Cypher was not present as a maternal mRNA and was absent during early development. Cypher mRNA was first detected at the 3-somite stage in adaxial somites, and as somites matured, cypher expression gradually enveloped the whole somite. Later, cypher expression was also found in the heart, in head and jaw musculature, and in the brain. We further identified 13 alternative spliced forms of cypher from zebrafish heart and skeletal muscle tissue, among them a very short form containing the PDZ domain but lacking the ZM (ZASP-like) motif and the LIM domains. Targeted gene knock-down experiments using cypher antisense morpholinos led to severe defects, including truncation of the embryo, deformation of somites, dilatation of the pericardium, and thinning of the ventricular wall. The phenotype could be rescued by a cypher form, which contains the PDZ domain and the ZM motif, but lacks all three LIM domains. These findings indicate that a PDZ domain protein is important for normal somite formation and in normal heart development. Treatment of zebrafish embryos with cyclopamine, which disrupts hedgehog signaling, abolished cypher expression in 9 somite and 15-somite stage embryos. Taken together, our data suggest that cypher may play a role downstream of sonic hedgehog, in a late stage of somite development, when slow muscle fibers differentiate and migrate from the adaxial cells.     

Culture supernatant of Lactobacillus acidophilus stimulates proliferation of embryonic cells

Our previous report showed that supernatants of Lactobacillus acidophilus (LS) cultures possessed chemotactic and angiogenic properties. Specifically, LS stimulated gene expression and the secretion of tumor necrosis factor-alpha (TNF-alpha), the proliferation of immune cells in vitro, and blood vessel formation. Chemotaxis and proliferation of inflammatory cells in vivo were also stimulated by LS. In the current study, we hypothesized that LS stimulates the growth and development of other rapidly dividing cells, including embryonic cells. The stimulatory effects of LS on a neuroblastoma cell line (Neuro-2a), chicken embryos, and bovine embryos were examined. The addition of LS to Neuro-2a cultures caused a proliferation of cells in a concentration-dependent manner. Pretreatment of LS at 56 degrees C for 30 mins did not affect its stimulatory activity. The administration of LS to the chorioallantoic membrane (CAM) of chicken-embryonated eggs for 1-2 days resulted in extensive thickening of the membrane. The thickening was due to the influx and proliferation of fibroblasts and inflammatory cells, the accumulation of loose connective tissue composed primarily of mucopolysaccharides, and/or the formation of blood vessels. Stimulatory effects of LS on bovine embryos were also observed. The treatment with LS significantly promoted the development of zygotes to the four-cell stage and from the four-cell stage to blastocysts. These results have confirmed our hypothesis that LS exerts a stimulatory effect on the cells of embryonic stages including neuroblastoma cells, the CAM of chicken embryos, and bovine embryos from zygotes to blastocysts.     

视黄酸对小鼠早期胚胎结构及0tx2基因表达的影响

以全反式视黄酸 ( all trans-retinoic acid,AT-RA)体外处理 EB( early allantoic bud)期和 LB( lateallantoic acid)期的小鼠胚胎 ,然后用洋地黄毒苷 ( digoxigenin)标记的 0 tx2反意义 RNA探针对整体胚胎进行原位杂交。以 4× 1 0 - 6 mol/ l的 AT— RA处理 ,抑制或减少了胚胎的前肠形成 ,经处理的胚胎的头褶没有对照的那样明显向腹部突出 ,其神经沟也不整齐 ;经处理的 EB期胚胎 ,其 0 tx2表达范围剧烈地向前退缩或只有很微弱的表达 ;但以同样浓度处理 LB期胚胎时 ,与对照相比 ,0 tx2的表达除了在极少数胚胎中变得弱一些以外 ,在绝大多数胚胎中其表达模式没有变化     

Skeletal muscle satellite cells appear during late chicken embryogenesis.

The emergence of avian satellite cells during development has been studied using markers that distinguish adult from fetal cells. Previous studies by us have shown that myogenic cultures from fetal (Embryonic Day 10) and adult 12-16 weeks) chicken pectoralis muscle (PM) each regulate expression of the embryonic isoform of fast myosin heavy chain (MHC) differently. In fetal cultures, embryonic MHC is coexpressed with a ventricular MHC in both myocytes (differentiated myoblasts) and myotubes. In contrast, myocytes and newly formed myotubes in adult cultures express ventricular but not embryonic MHC. In the current study, the appearance of myocytes and myotubes which express ventricular but not embryonic MHC was used to determine when adult myoblasts first emerge during avian development. By examining patterns of MHC expression in mass and clonal cultures prepared from embryonic and posthatch chicken skeletal muscle using double-label immunofluorescence with isoform-specific monoclonal antibodies, we show that a significant number of myocytes and myotubes which stain for ventricular but not embryonic MHC are first seen in cultures derived from PM during fetal development (Embryonic Day 18) and comprise the majority, if not all, of the myoblasts present at hatching and beyond. These results suggest that adult type myoblasts become dominant in late embryogenesis. We also show that satellite cell cultures derived from adult slow muscle give results similar to those of cultures derived from adult fast muscle. Cultures derived from Embryonic Day 10 hindlimb form myocytes and myotubes that coexpress ventricular and embryonic MHCs in a manner similar to cells of the Embryonic Day 10 PM. Thus, adult and fetal expression patterns of ventricular and embryonic MHCs are correlated with developmental age but not muscle fiber type.     

Gene Transfer into Older Chicken Embryos by ex ovo Electroporation

The chicken embryo provides an excellent model system for studying gene function and regulation during embryonic development. In ovo electroporation is a powerful method to over-express exogenous genes or down-regulate endogenous genes in vivo in chicken embryos¹. Different structures such as DNA plasmids encoding genes^2-4, small interfering RNA (siRNA) plasmids⁵, small synthetic RNA oligos⁶, and morpholino antisense oligonucleotides⁷ can be easily transfected into chicken embryos by electroporation. However, the application of in ovo electroporation is limited to embryos at early incubation stages (younger than stage HH20 - according to Hamburg and Hamilton)⁸ and there are some disadvantages for its application in embryos at later stages (older than stage HH22 - approximately 3.5 days of development). For example, the vitelline membrane at later stages is usually stuck to the shall membrane and opening a window in the shell causes rupture of the vessels, resulting in death of the embryos; older embryos are covered by vitelline and allantoic vessels, where it is difficult to access and manipulate the embryos; older embryos move vigorously and is difficult to control the orientation through a relatively small window in the shell.In this protocol we demonstrate an ex ovo electroporation method for gene transfer into chicken embryos at late stages (older than stage HH22). For ex ovo electroporation, embryos are cultured in Petri dishes⁹ and the vitelline and allantoic vessels are widely spread. Under these conditions, the older chicken embryos are easily accessed and manipulated. Therefore, this method overcomes the disadvantages of in ovo electroporation applied to the older chicken embryos. Using this method, plasmids can be easily transfected into different parts of the older chicken embryos^10-12.     

FLT4 基因在斑马鱼早期发育过程中的表达

目的:研究FLT4(VEGFR3)基因在斑马鱼早期发育过程中的表达。方法:提取斑马鱼胚胎的总RNA,制备地高辛标记的FLT4RNA反义探针,WISH(整胚胎原位杂交)研究FLT4在斑马鱼早期发育过程中的表达。结果:成功合成FLT4基因探针,获得FLT4基因在斑马鱼早期发育过程中的表达情况:FlT4在2-cell、32-cell、oblong、shield期前普遍性表达(0.75h、1.7h、3.7h、6h);24h在头部表达较多,特别是在ICM(intermediate cell mass,中间细胞群)区处有特异性表达;48h、72h在头部表达均较高表达。结论:FLT4在早期参与了血管的形成和造血的发生,在脑部和肾小管的发育中可能起到了重要作用。     

APLP2, a member of the Alzheimer precursor protein family, is required for correct genomic segregation in dividing mouse cells.

The mouse amyloid precursor-like protein 2 (APLP2) belongs to the Alzheimer peptide precursor family. A possible role in pre-implantation development had been suggested previously, and was investigated further by creating a large deletion in the genomic locus. While heterozygous mice developed normally, homozygous embryos were arrested before reaching the blastocyst stage. One-cell embryos which contained protein of maternal origin underwent a limited number of cleavages. The progressive disappearance of the protein at stages 4 and beyond correlated with the appearance of extensive cytopathological effects. Nuclear DNA contents of the arrested embryos departed widely from the normal 2-4C value, thus suggesting a role for the protein in replication and/or segregation of the embryonic genome. Embryonic mortality was not due to the untimely initiation of programmed cell death, and it occurred before the stage at which apoptotic cells normally appear. The same abnormal distribution of DNA contents was seen in primary cultures of Aplp2 +/- embryonic fibroblasts following transfection of an expression vector for Aplp2 antisense RNA with green fluorescent protein (GFP) expressed from a co-transfected construct. Daughter cells derived from a GFP-positive cell showed abnormal DNA contents both >4C and <2C, thus indicating a role for the protein in the mitotic segregation of the genome and establishment of the proper nuclear structure.